Seismic Upgradation of RC Beams Strengthened with Externally Bonded Spent Catalyst Based Ferrocement Laminates

Balamuralikrishnan, R.; Al-Mawaali, A. S. H.; Al-Yaarubi, M. Y. Y.; Al-Mukhaini, B. B.; Kaleem, Asima

doi:10.28991/hij-2023-04-01-013

Cited by 46 publications

(5 citation statements)

References 27 publications

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“…Additionally, RC beams made of lightweight or low-strength concrete have been strengthened by complete confinement using ferrocement [28,31,32]. Certain authors have employed an approach of "gluing" ferrocement onto reinforced concrete surfaces [33][34][35]. Furthermore, research has explored the ferrocement strengthening of predamaged RC beams [36][37][38][39].…”

Section: Introductionmentioning

confidence: 99%

Comprehensive Analysis of Ferrocement-Strengthened Reinforced Concrete Beam

Živković,

Blagojević,

Kukaras

et al. 2024

Buildings

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Starting with the premise that the choice of the optimal method for strengthening reinforced concrete (RC) structures is a complex task and that ferrocement strengthening is comparable to other advanced strengthening technologies due to its cost-effectiveness, ease of construction, and durability, this paper presents a comparative study of the flexural bearing capacity of RC beams strengthened with ferrocement strips applied by gluing. An overview of the life cycle assessment (LCA) based on embodied energy or CO2 is presented in the introduction, based on the existing literature review. The research includes tests of 15 RC beams of identical cross-sections (150/250 mm) and a span of 3000 mm. Strengthening was conducted by applying four types of ferrocement strips (different widths and wire mesh layers). Two factors were examined: the verification of the comprehensive FEM numerical model against the experimental results and the applicability of existing simplified calculation methods for sufficiently accurate results which could be used in regular practice. The results show that the failure forces obtained from numerical models and experimental models differ by no more than 3.94%. The increase in the bearing capacity of the strengthened models is up to 21.4%. The transformed area method for the cracked section showed good results when compared to the FEM and experimental models. The analytically calculated failure force is contingent upon the partial factor for variable action, which was explored within the 1.5–1.7 range.

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Section: Introductionmentioning

confidence: 99%

Comprehensive Analysis of Ferrocement-Strengthened Reinforced Concrete Beam

Živković,

Blagojević,

Kukaras

et al. 2024

Buildings

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“…As a result, more research on the seismic performance of these structures is required to achieve their highest level of earthquake resistance (23). In addition, by knowing the behavior of the structure and analyzing it accurately, it is possible to build new structures as well as repair, reconstruct, renovate and retrofit existing structures (24).…”

Section: Introductionmentioning

confidence: 99%

Seismic Assessment of Concrete Dams, Considering Anisotropy Caused by Lift Joints

Saeed,

Moradloo

2024

IJE

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Concrete dams are anisotropic due to lift joints that affect their performance. Lift joints are usually ignored in numerical analyses of concrete dams and the dam body is assumed to be homogeneous and isotropic. In this study, the seismic behavior of gravity dams was evaluated considering the anisotropy caused by lift joints, and the orthotropic and isotropic state responses were compared. Moreover, in the seismic loading range, a more detailed evaluation was done by applying the real effects of strain rate. Koyna concrete gravity dam was selected for the case study. The results showed that concrete anisotropy leads to larger dynamic displacements and greater damage to the dam body. By considering the orthotropic properties of concrete can lead to more realistic results. The maximum compressive and tensile stresses also increased in the anisotropic model compared to the homogeneous and isotropic model, indicating the usefulness of incorporating the orthotropic behavior of concrete in seismic analysis. In addition, considering the strain rate in the seismic loading range had an insignificant effect on the results. Therefore, considering the large dynamic increase factor in numerical analyses causes the error.

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“…The use of multicomponent concretes is growing due to their ability to manage structure formation and show directed quality in properties at all stages of technology (27,28). For example, Balamuralikrishnan et al (29) analyzed the flexural, shear, and combined effects of the flexural and shear behavior of reinforced concrete beams that were strengthened with externally bonded ferrocement laminates made with spent catalysts. They compared the results of these beams to control beams that were not strengthened.…”

Section: Introductionmentioning

confidence: 99%

Self-healing Concrete Using Microcapsules Containing Mineral Salts

Ghaemifard,

Khosravi,

Farash Bamoharram

et al. 2024

IJE

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Propagating micro-cracks in a structure decreases its load-bearing capacity and leads to the collapse of the entire structure. Addition of various additives in all kinds of concrete or concrete ingredients, as several studies have shown, could significantly make concrete reclaim from the specifications and attributes point of view. A possible manner to the common ruin and expensive preservation of concrete infrastructure, utilizing encapsulating healing factors is helpful for the self-healing of concrete. The selfhealing concrete with microencapsulated Preyssler, and calcium nitrate was studied in this paper. Microcapsules were synthesized by in-situ polymerization of urea-formaldehyde as a shell around the core materials inclusive of Preyssler, calcium nitrate. Physicochemical characterization of microcapsules was conducted by Fourier transformation infrared spectroscopy, field emission scanning electron microscopy, and Transmission Electron Microscope. The mechanical assessment of cementitious specimens with different dosages of microcapsules (0%,0.5%, 1%, 1.5%, and 2%) was performed by compressive tests. Also, by measurement before and after damage after 10 days, the self-healing potential was tested. After the concrete was damaged by exerting 30% of its final load, all samples were incubated by immersion in water. According to the results, the sample containing 0.5% UFN, the sample containing 1.5% UFP, and the sample containing 1.5% UFNP have higher repair rates than others. This scope of research because of its interdisciplinary nature would own several possibilities to be pioneering with making an opening gate to link sciences and engineering such as material, chemistry, science, nanotechnology, and the field of engineering to persuade a wide spectrum of contribution in engineering sciences and usages.

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Seismic Upgradation of RC Beams Strengthened with Externally Bonded Spent Catalyst Based Ferrocement Laminates

Cited by 46 publications

References 27 publications

Comprehensive Analysis of Ferrocement-Strengthened Reinforced Concrete Beam

Comprehensive Analysis of Ferrocement-Strengthened Reinforced Concrete Beam

Seismic Assessment of Concrete Dams, Considering Anisotropy Caused by Lift Joints

Self-healing Concrete Using Microcapsules Containing Mineral Salts

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